Promoters for swine complement inhibitors

ABSTRACT

The present invention provides the base sequence defined as Sequence No. 1, DNA comprising a part of the sequence, or DNA containing the sequence, and relates to a promoter gene of the porcine complement inhibitor. In generating transgenic pigs transformed with human complement inhibitor and/or such thrombosis-inhibiting factors as thrombomudulin (collectively termed the complement inhibitor), DNA of the invention can effectively be used to express the complement inhibitor by integrating the gene into the upstream part of the human complement-inhibitor gene. Since hyperacute rejection, which occurs on transplanting a porcine organ or tissue to man, can be prevented, xenotransplantaion of the porcine organs and tissues to man will become possible. Therefore, the problem of the lack of donors for transplantation can be solved.

This application is the national phase under 35 U.S.C. §371 of prior PCT International Application No. PCT/JP97/01677 which has an International filing date of May 19, 1997 which designated the United States of America.

TECHNICAL FIELD

This invention provides DNA consisting of a specific base sequence. More particularly, the invention provides a promoter gene for a porcine complement inhibitor.

BACKGROUND OF THE INVENTION

Recently, organ transplantation has widely been carried out in many countries. Development of highly effective immunosuppressants (e.g., Cyclosporin and FK506) has solved the problem of rejection of organs transplanted from man to man, however, lack of donors has become a serious problem. Such a problem has prompted studies on animal-to-man organ transplantation, namely xenotransplantation. Although approximately 3,500 instances of heart transplantation have been performed annually in European countries and the United States, they cover only 20 to 30% of patients who need heart transplantation. Use of animals closely related to human beings as donors (for example, such primates as baboons and chimpanzees) involves a great deal of difficulty due to shortage of these animals and their high intelligence, but use of domestic animals as donors involves less problems. Particularly, pigs have advantages of easy supply due to mass rearing, their organ sizes similar to those of man, and established basic technology including maintenance of the strains. Consequently, organ transplantation from pig to man has been studied.

Of rejections occurring in pig-to-man organ transplantation, acute rejection by major histocompatibility complex (MHC)-related cellular immunity may not occur, since evolutional relatedness between pigs and man is so scarce that there is no similarity between their MHCs. Moreover, application of the effective immunosuppressants may avoid such rejection, if ever occurs.

Human blood, however, contains endogenous antibodies against pigs (namely, natural antibodies). Consequently, if a porcine organ is transplanted to man, the natural antibodies recognize the organ (antigen) resulting in formation of antigen-antibody complexes, which activate human complements. The activated human complements cause necrosis of the transplanted organ (rejection). Such a phenomenon occurs immediately (within an hour) after transplantation, so it is termed hyperacute rejection.

No drug preventing hyperacute rejection caused by complement activation has ever been developed. No human organ is injured by human complements, since factors preventing complement activation are expressed in human organs. Such factors are named complement inhibitors (or complement-inhibiting factors). Of the complement inhibitors, three factors, DAF (decay accelerating factor, CD55), MCP (membrane cofactor protein, CD46) and CD59, are important. It is believed that DAF and MCP inhibit activation of complements by accelerating the destruction of C3b and C3/C5 convertase, and CD59 does so by inhibiting the C9 step.

The complement inhibitors are species specific. Porcine complement inhibitors can inhibit the complement activity of pigs but not that of man. The porcine complement inhibitors cannot inhibit human complements activated by the porcine organ transplanted to man. Therefore, the porcine organ transplanted to man undergoes necrosis.

Pig-to-man organ transplantation triggers not only hyperacute rejection but also thrombin formation and platelet coagulation, resulting in thrombosis in the hosts vascular system as well as the transplanted organ. Components of the blood coagulation pathway, such as thrombin, fibrin and fibrin degradation products may also amplify tissue damage, modify immune responses and augment inflammatory responses (Xenotransplantation, vol. 3(1). 24-34, 1996).

Such problems arising when a porcine organ is transplanted to man will be solved, if human complement inhibitors and/or such thrombosis-inhibiting factors as thrombomodulin (collectively termed as complement inhibitors in the following) are expressed in the porcine organs by genetic engineering. In transplantation of the porcine heart, there will be no problem if the human complement inhibitors are being expressed by porcine vascular endothelial cells.

From such a viewpoint, studies on recombinant pigs (transgenic pigs) integrated with human complement-inhibitor genes have widely been carried out.

It has also been considered to be useful to express such factors that are capable of suppressing thrombosis (e.g., thrombomodulin, Proceedings of the XVth World Congress of the Transplantation Society, pp. 77-79, 1995) with or without the human complement inhibitors in the porcine organs by genetic engineering.

As described above, xenotransplantation by using transgenic pigs integrated with the human complement-inhibitor genes have been studied. Up to the present, promoters derived from the human complement-inhibitor gene or viruses have been used to prepare such transgenic pigs. For the complement inhibitors to be expressed in pigs, however, the promoters originating from pigs may be more efficient. To obtain such promoters, cDNA of the porcine complement inhibitors is needed. Therefore, the present inventors carried out studies to isolate and purify cDNA encoding a porcine complement inhibitor (termed pMCP in the following) and succeeded in isolating and sequencing its cDNA (see Japanese Pat. Appln. No. 178254/1995).

The present inventors further studied and succeeded in identifying and sequencing the promoter region of PMCP by preparing porcine genomic libraries and then screening them with pMCP's cDNA as a probe.

As described above, pMCP's promoter of the invention was derived from pMCP's genomic DNA, which was isolated by using cDNA of pMCP. pMCP's cDNA was derived from RNA transcribed in porcine vascular endothelial cells. Namely, pMCP's promoter of the invention regulates expression of pMCP in the porcine vascular endothelial cells. Consequently, by using pMCP's promoter of the invention, genes of human complement inhibitors and those of such thrombosis-inhibiting factors as thrombomodulin can be expressed in the porcine organs, particularly the porcine vascular endothelial cells. Furthermore, by using pMCP's promoter of the invention, various structural genes can effectively, selectively and specifically be expressed in the porcine organs, particularly the porcine vascular endothelial cells.

On the other hand, the promoters derived from the human complement-inhibitor gene or viral genome, all of which had been employed in the previous studies, could neither selectively, specifically nor effectively express the human complement inhibitor in the porcine endothelial cells.

This invention was accomplished on the basis of such findings. The purpose of the invention was to provide DNA possessing an activity of pMCP's promoter.

DISCLOSURE OF THE INVENTION

This invention provides the base sequence defined by Sequence No. 1, DNA comprising a part of the base sequence, and DNA containing the sequence.

Another invention provides DNA with an approximately 4.1-, 2.4-, 1.7-,0.9-, 0.5-, 0.07- or 0.05-kb upstream sequence from the 3′end of the base sequence defined by Sequence No. 1; and DNA with the base sequence defined by Sequence No. 2.

These DNAs possess pMCP-promoter activities.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 shows the promoter activity of each promoter region.

FIG. 2 compares the promoter activities of the invention and hDAF.

THE BEST MODE FOR APPLYING THE INVENTION

The present invention is explained in detail in the following:

The base sequence of this invention defined by Sequence No. 1 is DNA with the promoter activity of pMCP. Such DNA can be obtained by preparing genomic DNA of the structural gene of pMCP from a commercially available porcine genomic library, identifying the promoter region existing on upstream region of genomic DNA, and digesting it with appropriate restriction enzymes.

With cDNA of pMCP or its parts as probes, genomic DNA of pMCP's structural gene can be cloned from porcine genomic library by the conventional plaque- or colony-hybridization method. By the plaque-hybridization method, plaques formed by phages containing the pMCP's genomic DNA are identified as follows: {circle around (1)} phages containing the porcine genomic library and E. coli are co-cultured on agar plates to make plaques; {circle around (2)} the plaques are transferred to nitrocellulose membrane filters, and then phage DNA in the plaques are fixed on the filters; and {circle around (3)} the phage DNAs are hybridized with pMCP's probes labeled with radioisotope, and then autoradiographes of the filters are taken. By repeating such procedures, phages containing the pMCP's genomic DNA can be cloned.

To select the positive phage clones containing the promoter region of the genomic DNA, a region corresponding to the known first exon of human MCP cDNA can be excised from pMCP's cDNA and used as a probe to perform the plaque hybridization similarly as mentioned above, since the promoter gene of pMCP is believed to possess the first exon.

Thus, pMCP's genomic DNA containing the promoter region can be prepared from the cloned phage DNA.

The promoter region's DNA of pMCP can be prepared by digesting the upstream region of pMCP's genomic DNA with proper restriction enzymes, examining promoter activities of digested fragments, and collecting the fragments possessing the promoter activities.

The promoter activity can conventionally be examined: e.g., integrating the restriction enzyme-digested fragment into a vector for luciferase-activity determination, transfecting the vector into proper host cells, incubating the cells for a certain period, lysing the cells and then determining fluorescence of luciferase in the cell lysate.

The promoter region of pMCP's genomic DNA was thus obtained from the porcine genomic library. As shown in Examples described in the following, a promoter region comprising approximately 5,400 bp was obtained. By sequencing the region by a conventional method, the base sequence defined by Sequence No. 1 (5,418 bases) was identified.

By digesting the promoter region with proper restriction enzymes and examining the promoter activities of the resulting fragments by the above-described method, the approximately 1,700-bp upstream region proved to possess a high promoter activity. By sequencing the 1,700-bp region, the base sequence as defined by Sequence No. 2 (1,622 bp) was identified.

As shown in Examples, regions shorter and longer as well than the promoter defined by Sequence No. 2 were also found to possess the promoter activities. Consequently, so far as the activity of pMCP's promoter is retained, DNA of the present invention may consist of a part of the base sequence defined by Sequence No. 1 or DNA containing the base sequence defined by Sequence No. 1.

DNA of the present invention may be used as a promoter to express not only pMCP but also various other structural genes. In such cases, appropriate regions can be selected from the entire sequence, depending on the structural genes to express, host cell, and host animal.

The present invention's DNA thus obtained possesses the promoter activity to express the structural genes including pMCP and can be used for various purposes. As described above, DNA of the invention can favorably be integrated into the upstream part of human complement-inhibitor genes and used to generate a transgenic pig transformed with the human complement-inhibitor genes. Particularly, DNA of the invention can express the complement inhibitor on the porcine endothelial cells. Moreover, DNA of the invention can be used as the promoter to express other various structural genes than pMCP gene.

DNA of the present invention is not restricted to that prepared by the above-described method, but includes those prepared by other methods. As far as possessing substantially the same promoter activity, it will be validated if parts of the base sequence are deleted or replaced or inserted with one or more than two bases.

INDUSTRIAL APPLICABILITY

DNA of the present invention is the promoter gene of pMCP. In generating the transgenic pigs transformed with the human complement-inhibitor gene, the promoter gene can be integrated into the upstream part of the human complement-inhibitor genes. Since tissues and organs of such transgenic pigs do not cause hyperacute rejection, they can be transplanted to man. Consequently, the problem of the lack of donors for transplantation can effectively be solved.

EXAMPLES

The present invention will specifically be explained in detail with examples, but the scope of the invention is not restricted to these examples.

Example 1

A. Obtaining the Promoter Region of pMCP

{circle around (1)} Cloning of a phage clone by hybridization

To obtain the genomic clones of PMCP, λ FIXII (Stratagene) and full-length pMCPcDNA (prepared by expression cloning and digestion of the expression vector with XhoI and NotI) were used for hybridization as the porcine genomic library and a probe, respectively. The plaque hybridization was carried out as follows:

First, two million clones of the above-described phage and an E. coli suspension were spread on 50 plates (totally 100 million clones). The phage clones formed plaques after overnight incubation at 37° C. To absorb the phages in the plaques, a sheet of nitrocellulose membrane filter for hybridization was placed on each plate for approximately 1 min.

After that, each filter was turned upside down and immersed in an alkaline denaturation solution (0.2 M NaOH, 1.5 M NaCl) to brake nuclei for 20 sec and then in a neutralizing solution [×2 SSC, 0.4 M Tris-HCl (pH 7.5)] for 20 sec. After drying, they were cross-linked under UV irradiation (GS Gene Linker, Bio Rad).

Second, these filters were blocked in a prehybridization buffer [50 % deionized formamide, ×4 SSC, 50 mM HEPES (pH 7), ×10 Denhardt solution, 100 mg/ml denatured salmon sperm DNA] for 4 h at 37° C.

The probe was labeled by treating pMCPcDNA with dNTP and Klenow (DNA polymerase I) in the presence of a radioisotope [α-³²P] ATP. A radioisotope-labeled reverse chain was thus prepared with the cDNA as a template. The reverse chain can hybridize with the phage clone having the identical DNA sequences.

Then, the radio-labeled probe was placed on a gel-filtration column, spun down to remove the nonreacted and nonlabeled nucleotides, incubated for 3 min at 90° C., chilled on ice to maintain a single-chain form of DNA, and subjected to hybridization.

The prehybridized filters were placed in HybriPack and hybridized overnight at 37° C. with the above-described probe in the hybridization buffer.

Next, the filters were washed twice with SSC and SDS, allowed to react with the image-analyzer plates for 2 h at room temperature, and then analyzed with an image analyzer (Fuji Film Co.).

Finally, 30 positive clones were obtained. Gels of the positive clones were sucked with Pasteur pipettes and diluted with SM buffer. The clone-containing solution was thus prepared.

{circle around (2)} The Secondary and Further Screening

The clone-containing solution was appropriately diluted and spread on plates (totally 30 plates). After that, hybridization was carried out again. Many positive plaques were observed on 20 plates. Twenty positive clones were thus obtained.

Such procedures were repeated three times. Finally, all of the clones were purified.

{circle around (3)} Classification of the Clones on the Basis of the Restriction-Enzyme Digestion Profiles

To confirm whether the clones were independent, they were digested with a restriction enzyme EcoRI and then electrophoresed. The identical clones exhibit the same digestion profile. From various digestion profiles, 10 distinct clones were thus obtained.

{circle around (4)} Selection of the Phage Clones Containing the Promoter Region By Using the cDNA's Leading Region

The phage clones containing the promoter region are believed to have the first exon. Consequently, a region supposedly corresponding to the first exon of human MCP was excised (SalI-SphI) from pMCPcDNA and subjected to hybridization as a probe. Four clones gave positive results.

{circle around (5)} Selection of the Promoter-Region Containing Phage Clones By Digestion With A Rare Restriction-Enzyme Site

Four clones were digested with FspI, since its restriction-enzyme site scarcely exists in the first exon of pMCPcDNA. Only one clone was digested with the enzyme.

Consequently, it was found highly possible that this phage clone contained the promoter region.

{circle around (6)} Confirmation of the Promoter Region By Sequencing

The phage clone was digested with a combination of FspI and another restriction enzyme (EcoRI) to localize the FspI site of the first exon at the terminal of the digested fragment, integrated into a sequencing vector pBSIIKS+ (Stratagene) and sequenced (373 DNA Sequencer, Applied Biosystems, Inc.).

The result showed that the phage clone certainly contained the first exon.

From the restriction-enzyme digestion profile, it was proved that this phage clone contained the pMCP's promoter region, of which the full length was approximately 13 kb upstream the genome.

B. Determination of the Activity of pMCP's Promoter Region

{circle around (1)} Preparation of A Construct For Assaying Promoter Activity

The promoter activity was determined with a system utilizing luciferase cDNA.

A 5.4-kb promoter region of pMCP bearing a T7 primer recognition site for sequencing (as the 13-kb DNA of the phage clone was too large to integrate, it was digested at the EcoRI sites) was digested with restriction enzymes BstEII and BssHII from the above-described sequencing plasmid. DNA sequence of the 5.4-kb promoter gene was conventionally determined as shown by Sequence No. 1 (5,418 bp).

The terminal of the above-described promoter region was blunted with T4 DNA polymerase and subcloned in the pGL-3 basic vector (Promega) for luciferase-activity determination at the SmaI sites. The vector for luciferase activity determination itself lacks a promoter gene, so it is useful to evaluate the promoter activity by integrating a to-be-tested promoter into the upstream part of the luciferase gene and determining luciferase activity. The luciterase activity can be determined by lysing transformed cells to prepare enzyme-containing lysate, allowing the lysate to react with a substrate of the enzyme and reading emitting fluorescence intensity.

{circle around (2)} Preparation of Deletion Mutants

To obtain the promoter regions of various sizes, deletion mutants were prepared with a Kilosequence kit (Takara).

A series of pGL-3 vectors bearing promoters of 4.1-, 2.4-, 1.7-, 0.9-, 0.5-, 0.07- and 0.05-kb lengths were thus prepared.

Similarly, a pGL-3 vector bearing an SV40 promoter was prepared for control.

Furthermore, a vector bearing a reversed sequence of the above-described 5.4-kb promoter and that bearing human DAF (hDAF) promoter (approximately 4 kb) were also prepared for comparison.

{circle around (3)} Electroporation of the Plasmids Into Porcine Aorta Endothelial Cells

Luciferase activities were determined by using a porcine aorta endothelial cell line.

Cultured cells were detached with trypsin/EDTA solution, washed and suspended in HeBS buffer at a concentration of 3×10⁶ cells/800μl.

A 800-μl portion of the cell suspension and a 15-μg portion of the above-described plasmids were transferred to a cuvette with 0.4-cm electrode clearance (a cuvette for cell electroporation) and electroporated with a Gene Pulser (Bio Rad) at 500μF and 300 V. The plasmids were integrated into the cells.

{circle around (4)} Determination of the Luciferase Activity

The above-described cells were cultured for 48 hours, collected, washed with PBS and treated with the cell-lysing solution for 10 min. Tenμl of the cell lysate was mixed with 50μl of the substrate of luciferase. Fluorescence of the reaction mixture was read with a Luminescence Reader (Aloka).

The results are shown in FIG. 1. The activities per 1×10⁵ viable cells were calculated. Each column shows a relative activity, where the activity of a control pGL-3 vector bearing SV40 promoter is defined as 100. In FIG. 1, a symbol of −5.4 kb means a vector bearing a reversed fragment of about 5.4-kb promoter region. Similarly, that of hDAF means a vector bearing the hDAF promoter.

From the luciferase activities, the activities of the promoters ranging from approximately 0.07 to 1.7 kb were higher than that of the positive control, which was higher than hDAF promoter's activity (FIG. 1). Activities of the promoters of approximately 5.4-, 4.1-, 2.4- and 0.05-kb lengths were also noticed. The vector bearing the reversed fragment, however, showed no activity. From these results, it was evident that the above-described regions certainly possessed promoter activities.

Example 2

Sequencing the Promoter Region

DNA of an approximately 1.7-kb promoter region possessing a high activity as shown in FIG. 1 was sequenced.

With the T7 primer-recognition site which had been integrated into the upstream site of each deletion mutant, DNA was sequenced by the dye primer method. Sequencing was repeated twice. With regions difficult to identify, they were subcloned into pBSIIKS+and sequenced by using the T3 primer recognition sites.

As a result, it was evident that the above-described approximately 1.7-kb promoter region possessed the DNA sequence as defined in Sequence No. 2 (1,622 bases).

Example 3

Determination of the Promoter Activity (Expression of the Human Complement Inhibitor)

{circle around (1)} Transfection

hDAFcDNA was connected to each of 5.4-kb (Sequence No. 1), 1.7-kb (Sequence No. 2) and 0.9-kb PMCP promoters or hDAF promoter. These genes were linearized, additionally ligated with a neomycin resistance gene as a selection marker and transfected into to 3×10⁶ porcine cells by electroporation at 500μF and 300 V with a Gene Pulser (Bio Rad). The cells were cultured in a culture medium containing 250 μg/ml neomycin sulfate (Gibco). Colony-forming cells were collected. Expression of hDAF on the cell surface was analyzed with an FACScan (Becton Dickinson) after staining the cells with biotinylated anti-hDAF monoclonal antibodies (IA10,IIH6 and VIIIA7; Kinoshita, T., et al.(1985) J. Exp. Med. 162: 75) and PE-conjugated streptavidin.

{circle around (2)} Assay for Complement Resistance

Some clones obtained by the above-described method were selected. Fifteen-thousand cells of each clone were allowed to react with antibodies and complement in a 96-well plate. As the antibodies, 100 μl of inactivated human serum was added to each well and allowed to stand for 30 min at 4° C. After washing with PBS, appropriately diluted normal human serum was added to each well as a complement source and allowed to stand for 3 h at 37° C. Surviving cells were determined with a WST-1 (Behringer Mannheim).

{circle around (3)} Results

1. Comparison of Expression with Various Promoters

A part of the results indicating relationship between each promoter and hDAF expression is shown in FIG. 2.

The horizontal axis of FIG. 2, FL2-H, represents the amount of hDAF expressed; it increases as the axis shifts rightwards. The vertical axis, count, represents cell number; it increases as the axis shifts upwards. Each peak shows the activity of a promoter indicated by the label. Black and blank peaks indicate FACScan responses obtained by cells reacted without and with anti-hDAF antibodies, respectively. As a result, no HGAF was expressed without the promoter. Comparing with hDAF promoter, any of pMCP promoters expressed hDAF effectively more than 20 times. Namely, it was confirmed that approximately 5.4-, 1.7- and 0.9-kb promoters effectively expressed the human complement inhibitor in the porcine endothelial cells.

2. Comparison of Resistance Against Complement By Various Promoters

No resistance was noticed in 50% human serum, if hDAF was expressed by the hDAF promoter; whereas, resistance of more than 80% was noticed even in 100% human serum, if hDAF was expressed by the pMCP promoters. Therefore, it was confirmed that hDAF exhibited its original function and resisted against the human complement, if hDAF was expressed on the porcine endothelial cells by the pMCP promoters.

2 1 5418 DNA Porcine sp. n = g, c, a, or t 1 gaattctgcg tacacggggc cccggtggct ttacatcatc gctacagcga catgggatcc 60 gagccgtgtc tacaacctac acaacaacgc cagatcctta acccaatgca tgaggacagg 120 gctcaaacct gcggcctcat agatgctagt cagattcgtt tctgctgagc cacaatggga 180 actcctaatt ctagatcgat ctagaattag gagttcccat tgtggctcag cagaaacgaa 240 tctgactagc atctatgagg ccgcagtttg agccctgtcc tcatgcattg ggttaaggat 300 ctggcgttgt tgtgtaggtt gtagacacgg ctcggatccc atgtcgctgt agcgatgatg 360 taaagccacc ggggccccgt gctacgcaga attcntgcag cccgggggat ccactagttc 420 tagcnagaga gttgaaaatt taaagaacat ttctccccta atctcccaaa atatgggcaa 480 aggacaggta cccgtggcac tggaaaaata caggcaagca acccatgagt acatgaaaag 540 atgctccagg gttcggccta atggaagcct gaacaatgcc tatcacatcg tgggtttctg 600 aagaagtaac ttaaagaaac tagaaattaa atggctttct tagaatgaaa attctctatc 660 acaaggaaaa atgttgtatg ttgtttttcc cataatggag gtcagtgggc gctatgatta 720 acaaatatct gatgcctgtg actttttaat tgcaagaaat ctgtgnagtt tttttattat 780 ctatgggaaa tattgcatat attaatgata tcacctaact tgtattattg agcaattctg 840 tccacatctg gcctttcatc tttcatctaa aaagcagggg ctggaccaac tgaccttcag 900 tgccattctt actgctaaca ttctaatttt gtttttattg cctttttgta caaaagtgtg 960 agagaagtca ttttaagtct gtgacattaa atgtaatttt ctgtctccag cattataata 1020 agaatcaaag atttaatcta atacaccgat ggaatattgt ttataacgta tttactgttt 1080 caagccttca aaaccaagag aaaacaaaat gagtacctgt tccttctgag aaatgccctt 1140 cttcctgttc agaatccctg tgtataacag gaatgctctc gagttaacag ccaagtaaga 1200 ggcccatcgg ctggcaggtg cccacctagc taggtgcaag cagaggtggc agtgctccca 1260 ggaccaacag cagaaacatg gcttaactat cctgtgttta gcagttctct tacgggtttt 1320 cacaacacct aaaaagcgcc ctgatggggt aaagcctctg ccttcatgct gctgccccgt 1380 ctctgaaaag caggacgtaa atatacaatt taggaggtaa gagggacatc tgccattgtt 1440 ttctttaaca cagtcagcct ctgtttaatg aatcccagcc acctccctcc acctaccatc 1500 attcctaagg tttgcagagg agctgccata gagctcaaaa cacggwntac agacaagcat 1560 nttctccatc cctcctcatc ttctcacagg ccgcttgaca acatctctag gagggggtgg 1620 aggcgccacc agtgtttgag cccctcgttc acgcaaagcc ttgactctgg agttctagtc 1680 ctcgcgggac cttaggaagt tcacggtcaa tactccgccc ttgggctcag acactaagag 1740 gatctccggg taaagagata gacagtagct ccatgcctga tttaggaaaa ctgtccgtac 1800 agacagttgt aattcattcc tttcagagac aaatcctgct ctcttcctag ttcctgaagt 1860 cattaaaatc aaaagctctc agaaacgtcc cagcatttgc taagtccacg ctgggggagg 1920 atgggcagag ccgtgttcag cgcgtttgac agcaacaccc acttatttca ttyagtatcc 1980 ataggcatat atcatgcacc tggtataggc ctctctctca gcactggaga tacagcaaga 2040 aaacgctatt cctgccccat ggagcttgtw maraaaaata gannnaaaaa ccctttanaa 2100 anggaagctr ccngmtgggn cmaagtnaaa attaagtaaa aagaaawccg tgarraaacc 2160 cttcagtnat attaagaaag aaantagctt gatgaaaccc caggtgtana aattnncact 2220 aaaacaatgs tcccaattaa aacccccmaa ttcatggaat ttactcnagt ancctgnaac 2280 taggraaacc aaattctagc cnatagtttc tcccttctaa atnttctcat gagaaaacaa 2340 yttatttcca aaganatttt ccatgatggg gaaagttttt ttcaactttg ctcaggtata 2400 aactgaanat acagcattaa agtaaagata gttgcagaga ccaccaaata gatacccgtt 2460 ttcanaaaaa gtgccaacat ggagccagag aacatttccg ttacatcacg cttttacggc 2520 tttgaaaatt aacagagatg ataatccccc mccttgggtt tccnactccn tccctcctna 2580 attttacctc ctttaattgt catcatgtct ggagattata atccaagata ctaagatgtt 2640 tatntcatac atcgcctcca cacagtgtgt ctnanaagct cttgcaagaa tccaaacatt 2700 gtgctggtct gggtagaaaa ggaaattcca tggtttgttg aacccaggaa ctcttcagta 2760 catctccgag gtaaaactgt ttaaatacaa ttaaagttct acagttaaag ggtaccctcc 2820 tccactgttg gtgggaatgt aaactggtac aatcactatg aaaaacagga tggaggtact 2880 tcagaaaatg aagtatagaa ctaccacagg atccagcact ctcactcctg ggcacctatc 2940 aggacaaaaa attcgctgca aaagatgcat gcacccatag ctatgttcac tgcagcagca 3000 ttcacaatag ccaagacatg gaaacgacct aaatgtccat caacagctga atgcattaag 3060 aagacgtggt atatacacac aatggaatac tactcaagtc atgaaaaaga acaaaagaat 3120 gccatttgca gcaacatggc atggctggaa ctagagactc atgctaaatg aagtcagtga 3180 gaaagagaaa gacaaatacc acatgatatc acttatatct ggaatctaat atacgacaca 3240 catgaaactt tccacagaaa agaaaacctn catggacttt ggagaacaga cttgtggttt 3300 csccaagggg ggargggggg aagaccgtgg gaggactggg gagctttggg gttaatagat 3360 gcaaaactat tgcctttnga atggataagc caatgggatc ctgctgtacc agaaccrggg 3420 aactatanct agtcacttgc kntagaacat gatggaggat natntgagan aaagaatatn 3480 tgtgtgtgtk agagagagag agactggctc cactttgctg tatagtagaa aactgacaga 3540 acaccgtaaa ccattaaata aaaatccagt aaaaatttaa aaataaaaac acacattggt 3600 tccaatgtgt ttaaaagcaa taaagttcta taattgcagc agatgcatct gaggtttaca 3660 cggagagctt ccattcctta ccatcctctc attccttaac tctaatgtga tacaggttct 3720 attctcacca ttctatgaac aaaagagcag ctgatttaca ggttggattt ttcaaaaaaa 3780 aaaatttctt taccaggatc ccaaatgtaa caaagggtca atatagaaaa cttaaaaagc 3840 acagccaaag agaaatatac ataagccttt caactattaa ttttgattaa tatccaacga 3900 atctcttttt aagtgtatca atatattatt cattttaata aaagaaattg caagaggcac 3960 ttgctttttc tgcttacaaa tacggtttct caaatcgatt ttttttatat actgtttgca 4020 tagaatttca atccataaag ctacctattg aaaattcctt atatttctgc taaacactta 4080 agggcttata ttttctccaa atttatacat ccttgctcac agttctgacg atgtctttgg 4140 gataaactct aaatggaact agaggtttaa aagttatgtc catttaaaac ttttaacaca 4200 aaaaaaggta agttaaaaag taaaagtttg gggaggctgc tggtcgcccc cccaacattg 4260 gctgacattt ttattctttg acaacaaata ggaagaaaat gtcaatgtct ttttttactg 4320 cttaatactg gtcatgttac ttttctttcc ttttgctaat catacaggct tactcacaac 4380 tctacaaaaa aatcttactc attcctaatg ttccttcatt gagagattgg tttgccggaa 4440 acgttctcac tctcaccaag tcccaacagt cccaactcta acgacggtcg ctgcttccag 4500 aaatacggca cttaaggcac cctcgtcctt acctttttca tgcatgtgta tttcattttc 4560 aataaaacat tgagttgttc caaggccaga ccatagagtt gagccccaac atgctagtgg 4620 cccagtgtga tgtaataatt taccttccca ggggtcctct ccgggggggt acaggcgaga 4680 ctaagtgact ttaagctgtt gggagaacaa tggccaaacc tttcgtgatt ttgaaatcta 4740 tcaggccacg agacacttcg gtagcggacg ctcaaccctg ggaatcccaa ctattgtccc 4800 aaattttgcc tgactcgtgc caaagattga gccagggccc gggtgtccag gcagtctgca 4860 gtgccccagt ccccaccaga gccctgaagg gtgtcgggcc ccacgaaacc gctgcccggg 4920 ctctagggtt tctgttttca ggtcgctgcg ctttattctc taattcagcg ttcccgaaag 4980 agaccatgag gacccgccca gtgtccttta caccttcccg tgtcgggtgg cgacagctgt 5040 ttacgaagaa gagtgcacca ccctttcccg caagccgcag cggttagttc cgcagaagga 5100 ggagccaggg cgtcgggccg cagctgggag agaggcccgg cagcgggcgc cgcggagcag 5160 caagggcgtc cctctctcgg ccggagcccc gccccgcccc gcccccacgg ccccgccttg 5220 cggcccgccc attggctccg ccgggccctg gagtcactcc ctagagccac ttccgcccag 5280 ggcggggccc aggccacgcc cactggcctg accgcgcggg aggctcccgg agaccgtgga 5340 ttcttactcc tgctgtcgga actcgaagag gtctccgcta ggctggtgtc gggttacctg 5400 ctcatcttcc cgaaaatg 5418 2 1622 DNA Porcine sp. 2 gatcccaaat gtaacaaagg gtcaatatag aaaacttaaa aagcacagcc aaagagaaat 60 atacataagc ctttcaacta ttaattttga ttaatatcca acgaatctct ttttaagtgt 120 atcaatatat tattcatttt aataaaagaa attgcaagag gcacttgctt tttctgctta 180 caaatacggt ttctcaaatc gatttttttt atatactgtt tgcatagaat ttcaatccat 240 aaagctacct attgaaaatt ccttatattt ctgctaaaca cttaagggct tatattttct 300 ccaaatttat acatccttgc tcacagttct gacgatgtct ttgggataaa ctctaaatgg 360 aactagaggt ttaaaagtta tgtccattta aaacttttaa cacaaaaaaa ggtaagttaa 420 aaagtaaaag tttggggagg ctgctggtcg cccccccaac attggctgac atttttattc 480 tttgacaaca aataggaaga aaatgtcaat gtcttttttt actgcttaat actggtcatg 540 ttacttttct ttccttttgc taatcataca ggcttactca caactctaca aaaaaatctt 600 actcattcct aatgttcctt cattgagaga ttggtttgcc ggaaacgttc tcactctcac 660 caagtcccaa cagtcccaac tctaacgacg gtcgctgctt ccagaaatac ggcacttaag 720 gcaccctcgt ccttaccttt ttcatgcatg tgtatttcat tttcaataaa acattgagtt 780 gttccaaggc cagaccatag agttgagccc caacatgcta gtggcccagt gtgatgtaat 840 aatttacctt cccaggggtc ctctccgggg gggtacaggc gagactaagt gactttaagc 900 tgttgggaga acaatggcca aacctttcgt gattttgaaa tctatcaggc cacgagacac 960 ttcggtagcg gacgctcaac cctgggaatc ccaactattg tcccaaattt tgcctgactc 1020 gtgccaaaga ttgagccagg gcccgggtgt ccaggcagtc tgcagtgccc cagtccccac 1080 cagagccctg aagggtgtcg ggccccacga aaccgctgcc cgggctctag ggtttctgtt 1140 ttcaggtcgc tgcgctttat tctctaattc agcgttcccg aaagagacca tgaggacccg 1200 cccagtgtcc tttacacctt cccgtgtcgg gtggcgacag ctgtttacga agaagagtgc 1260 accacccttt cccgcaagcc gcagcggtta gttccgcaga aggaggagcc agggcgtcgg 1320 gccgcagctg ggagagaggc ccggcagcgg gcgccgcgga gcagcaaggg cgtccctctc 1380 tcggccggag ccccgccccg ccccgccccc acggccccgc cttgcggccc gcccattggc 1440 tccgccgggc cctggagtca ctccctagag ccacttccgc ccagggcggg gcccaggcca 1500 cgcccactgg cctgaccgcg cgggaggctc ccggagaccg tggattctta ctcctgctgt 1560 cggaactcga agaggtctcc gctaggctgg tgtcgggtta cctgctcatc ttcccgaaaa 1620 tg 1622 

What is claimed is:
 1. An isolated DNA comprising SEQ ID NO:1 or isolated DNA comprising a part of the sequence, wherein said part has a size of at least 0.05 kb from the 3′ end of the base sequence defined as SEQ ID NO:1.
 2. Isolated DNA comprising 4.1, 2.4, 1.7, 0.9, 0.5, 0.07 or 0.05 kb from the 3′ end of the base sequence defined as SEQ ID NO:1 as claimed in claim
 1. 3. Isolated DNA comprising a base sequence defined as SEQ ID NO:2 as claimed in claim
 1. 